Evidence for past interaction with an asymmetric circumstellar shell in the young SNR Cassiopeia A

TL;DR

This study uses 3D MHD simulations to demonstrate that asymmetries in the reverse shock of Cassiopeia A can result from its interaction with an asymmetric circumstellar shell formed by a massive eruption of the progenitor star.

Contribution

It provides the first detailed simulation-based explanation linking reverse shock asymmetries in Cas A to interaction with a specific asymmetric circumstellar shell.

Findings

Asymmetries in reverse shock can be explained by interaction with an asymmetric shell.

The shell likely resulted from a massive eruption 10^4 to 10^5 years before supernova.

The shell's mass is estimated to be around 2 solar masses.

Abstract

Observations of the SNR Cassiopeia A (Cas A) show asymmetries in the reverse shock that cannot be explained by models describing a remnant expanding through a spherically symmetric wind of the progenitor star. We investigate whether a past interaction of Cas A with an asymmetric circumstellar shell can account for the observed asymmetries. We performed 3D MHD simulations that describe the remnant evolution from the SN to its interaction with a circumstellar shell. The initial conditions are provided by a 3D neutrino-driven SN model whose morphology resembles Cas A. We explored the parameter space of the shell, searching for a set of parameters able to produce reverse shock asymmetries at the age of 350 years analogous to those observed in Cas A. The interaction of the remnant with the shell can produce asymmetries resembling those observed in the reverse shock if the shell was asymmetric with the densest portion in the nearside to the northwest (NW). The reverse shock shows the following asymmetries at the age of Cas A: i) it moves inward in the observer frame in the NW region, while it moves outward in other regions; ii) the geometric center of the reverse shock is offset to the NW from the geometric center of the forward shock; iii) the reverse shock in the NW region has enhanced nonthermal emission because, there, the ejecta enter the reverse shock with a higher velocity (between 4000 and 7000 km/s) than in other regions (below 2000 km/s). The asymmetries observed in the reverse shock of Cas A can be interpreted as signatures of the interaction of the remnant with an asymmetric circumstellar shell that occurred between 180 and 240 years after the SN event. We suggest that the shell was, most likely, the result of a massive eruption from the progenitor star that occurred between $10^4$ and $10^5$ years prior to core-collapse. We estimate a total mass of the shell of the order 2 Msun.